Pre-Hospital Emergency Care (PHEC) PDF

Summary

This document provides guidelines for pre-hospital emergency care, focusing on abdominal, loin, and scrotal pain. It outlines potential causes, risk factors, and treatment strategies in various situations, including surgical, gynecological, and medical etiologies. The document also highlights the importance of a thorough assessment of symptoms, considering pain location, onset, and associated factors to aid in diagnoses and ensure appropriate patient management.

Full Transcript

MPHEC:

Pre-Hospital Emergency Care (PHEC) refers to the management of patients outside
of a Medical Treatment Facility (MTF).

Abdominal, loin and Scrotal Pain:

▪ Low threshold for transport to hospital/MTF, especially in the elderly.
▪ Assume that everyone >50 with abdominal pain has an aneurysm and that
every woman of child-bearing age with abdominal pain has an ectopic
pregnancy until DEFINITIVELY proven otherwise.
▪ Support deranged physiology enroute to hospital.
▪ If able, consider giving antibiotics if significant intra-abdominal infection is
suspected - Ceftolozane/tazobactam, Amoxicillin.
▪ Many relatively benign causes (biliary colic, gastroenteritis) can be extremely
painful and mimic more severe pathology.

Consider causes by: Etiology and/or Location of pain

Etiology:
Surgical Etiology Gynecological Medical Aetiology
Etiology
Aortic aneurysm and Ectopic pregnancy Myocardial Infarction (Heart
dissection May present with Attack): Blockage of blood flow
non-specific to the heart muscle, causing
May present with symptoms, e.g. tissue damage.
abdominal pain, back pain syncope, urinary Chest pain/pressure, shortness
or renal colic-like pain. symptoms, of breath, sweating, nausea, and
diarrhoea or pain radiating to the arm or jaw.
shoulder tip pain
without a 'missed
period'.

Bowel ischemia (Condition Placental Diabetic Ketoacidosis (DKA): A
where blood flow to the abruption, serious complication of diabetes,
intestines is reduced or where high blood sugar leads to
completely blocked, leading Heavy vaginal the buildup of ketones in the
to tissue damage due to a bleeding and other blood.
lack of oxygen and pregnancy
nutrients) complications Excessive thirst, frequent
(e.g. mesenteric infraction urination, fruity breath odor,
(Mesentry is the tissue nausea, vomiting, abdominal
supplies blood to the pain, and confusion.
intestines is obsutrctured
often due to a clot) or
volvulus (when a loop of
the intestine twists around
itself, causing a blockage
and cutting off blood supply,
potentially leading to bowel
ischaemia)

Typically presents with pain
out of proportion to the
clinical signs in older
patients.

Peritonitis (inflammation of Ovarian Torsion: Lower Lobe Pneumonia:
the peritoneum, the thin Ovary twist around Infection affecting the lower part
layer of tissue that lines the the ligaments that of the lungs.
inside of the abdomen and support it, cutting off
covers most abdominal its blood supply. Cough, fever, shortness of
organs- caused by infection, breath, chest pain, and crackles
injury, bacteria) heard in the lower lungs.
 Presents with
Caused by free bowel sudden, severe
contents/acid/blood. pelvic pain, nausea,
vomiting, and
possible abdominal
tenderness,
requiring emergency
surgical
intervention.
Acute bowel obstruction Mittelschmerz Sickle Cell Crisis: A painful
(is a sudden and complete Pain due to episode in patients with sickle cell
or partial blockage of the ovulation. disease due to blockage of blood
intestines, preventing the vessels by abnormally shaped
normal passage of food, Benign preovulatory red blood cells.
fluids, and gas through the lower abdominal Sudden severe pain (especially
digestive tract) pain that occurs in bones, chest, or abdomen),
midcycle (between fever, swelling, and difficulty
Pain, total days 7 and 24) in breathing.
constipation(including women
flatus) and vomiting with
distended abdomen.

Testicular torsion Hypercalcemia: Abnormally high
levels of calcium in the blood.
Pain may be referred to the
abdomen. Nausea, vomiting, constipation,
confusion, fatigue, and frequent
urination.

Urinary obstruction Abdominal Migraine:
Recurrent episodes of abdominal
An enlarged bladder can be pain, primarily in children, often
missed if not percussed. linked to migraine.

Severe, dull abdominal pain,
nausea, vomiting, and pallor,
often without headache.

Abscesses (subphrenic, Gastritis: Inflammation of the
pelvic or psoas abscess - stomach lining.
Psoas abscess is a rare but Upper abdominal pain, nausea,
serious infection that occurs vomiting, bloating, and
in the psoas muscle, which indigestion.
runs from the lower spine
through the pelvis to the
femur)
 Pain and fever but may
have few localising signs.

Inflammatory Bowel Disease
(IBD): Chronic inflammation of
the digestive tract, including
Crohn's disease and ulcerative
colitis.

Abdominal pain, diarrhea (often
bloody), weight loss, and fatigue.

Irritable Bowel
Syndrome (IBS): A functional
gastrointestinal disorder causing
chronic abdominal discomfort and
altered bowel habits.
Abdominal pain, bloating,
diarrhea, constipation, or
alternating both.

Risk stratify either by age and likely pathology, or abnormal vital signs, then treat
pain and abnormal vital signs before transferring to an appropriate destination. - Can’t
diagnose all problems pre-hospital often will need a CT scan.

Military: Non-trauma Abdo pain is non-life-threatening and managed at R1 Whereas
rarer surgical emergencies may need prolonged transfer to R2.

Location:

Right subcostal:
Epigastric:

Left subcostal:

Right flank and groin:
Central Abdomen:

Left flank and loin:

Right Iliac Fossa:
Lower abdomen:

Left Iliac Fossa:

Location, nature and severity of pain:
The pattern of pain may change over time - e.g. early appendicitis, mesenteric
ischemia or bowel strangulation may begin as colicky pain (intermittent cramp like pain)
and then become constant as the condition progresses; pain may localize as the
parietal peritoneum becomes involved.

The location of pain is not always a direct indicator of the cause. In some instances the
pain can be experienced as referred in pain in a different area of the body.

Pain and area radiated to:

Onset of pain:

Very sudden onset of pain suggests rupture or torsion of an organ (e.g., ruptured
aneurysm, ectopic pregnancy, torsion of testis or ovary).
Systemic symptoms: Fever, night sweats, weight loss
Vomiting: May be due to severe pain (e.g., testicular torsion) gastroenteritis or
obstruction
Bleeding: Upper GI (hematemesis or melaena) or lower GI (rectal bleed)
Vaginal bleeding or discharge: Consider gynaecological/obstetric causes.
Past medical history: Note any similar episodes, note previous illness or surgery, note
Medication/allergies/last meal

Critical Abdominal Diagnoses in Military Personnel

Appendicitis: Often dull lower abdominal pain which might
be colicky in nature progressing to sharp, constant right
iliac fossa pain, tenderness and local peritonitis. Suspect
any person with significant abdominal pain with focal
tenderness in RIF.

Ectopic pregnancy: Suspect in any woman of child-bearing
age with abdominal pain, especially if abnormal vital signs
(evidence of shock) or PV bleeding. Typical time of
presentation is 4-8 weeks into a pregnancy (only one missed period if regular).
Ectopic pregnancy can be fatal.

Peritonitis: Peritonitis is inflammation in your peritoneum, the tissue that lines the
inside of your abdominal cavity. It's usually caused by an infection, and sometimes by
irritating bodily fluids. Always suggests significant pathology although the early signs
can be subtle and non-specific (i.e. they might not be peritonitis).

Loin Pain: (portion of the body below the rib cage and just above the pelvis)

▪ Consider Abdominal Aortic Aneurysm (AAA) in anyone >50.
▪ Renal stones are relatively common however first
presentation of renal stones in the elderly or in children is
uncommon.
▪ Pyelonephritis (Pyelonephritis is a kidney infection that's
usually caused by a bacterial infection) and urinary infections
are more common in women
▪ Back pain is very common in all age groups.

Signs and Symptoms:
 ▪ Pyrexia – Pyelonephritis or abscess
▪ Hypotension – Ruptured abdominal aortic aneurysm
▪ Respiratory system examination- Basal pneumonia
▪ Abdominal examination – Several abdominal conditions can
radiate to the back including pancreatitis
▪ Back examination

Ruptured Abdominal Aortic Aneurysm:

An abdominal aortic aneurysm (AAA) is a swelling in the aorta, the artery that carries
blood from the heart to the tummy (abdomen).

Transfer as an emergency to surgical Centre. Check which hospital with ambulance
control as often a regional vascular on-call.

Typically seen older patients, risk factors same as ischemic heart disease, typically
present with flank/back pain and collapse, pain in stomach and back and pulsing
feeling in tummy. Patients are often aware they have an aneurysm after screening.

Renal Colic: ( Kidney stone)

Renal or ureteric colic generally describes an acute and severe loin pain caused when
a urinary stone moves from the kidney or obstructs the flow of urine

May require role 3 capabilities such as CT scanning to determine if a stone is
obstructing the kidneys. Confirmed renal colic will inevitably lead to aeromed home.

▪ Pain is sudden in onset, very severe and the patient is often writhing around.
▪ Pain may radiate to the groin and anteriorly.
▪ Often there is tenderness over the renal angle.
▪ Renal colic is rather more constant and persistent than biliary colic (temporary
blockage due to gallstrones).
▪ Ask about blood in the urine - There is gross or microscopic haematuria in 85% (in
the other 15% absence of gross or microscopic haematuria does not exclude renal
colic).
▪ A stone that is moving may be more painful than one that is static.
▪ There should be no hypotension and opiate analgesia is likely to be required.
Pyelonephritis:

Pyelonephritis is a kidney infection that's usually caused by a bacterial infection. Can
rapidly progress to severe sepsis and is not uncommon in younger (especially
female) patients. Loin pain with features of sepsis needs urgent antibiotics and fluids
and transfer to a medical treatment facility.
▪ The patients with pyelonephritis is ill, often with a very high temperature and
rigors.
▪ There may be symptoms of urinary tract infection and vomiting.
▪ Pain, in contrast to renal colic, is often a constant dull ache.
▪ If signs and symptoms of systemic sepsis, consider early antibiotics and
intravenous fluids.

Testicular Torsion:

Requires a low threshold of suspicion and immediate referral. Manage pain en route
and take to nearest surgical facility.

Is an emergency

▪ Difficult to exclude on clinical grounds; may mimic epididymo-orchitis (a
condition that involves inflammation, swelling, and pain of the epididymis and/or
testicles).
▪ Common in teenagers; rarer >30 years of age.
▪ Sudden or gradual onset; may have had previous self-limiting pain episodes.
▪ Painful; usually severe pain, which may radiate to the abdomen - always
examine the testicles in younger males with severe abdominal pain.
▪ Cremasteric reflex is almost always absent. The cremasteric reflex is a
superficial (i.e. close to the skin's surface) reflex observed in human males. This
reflex is elicited by lightly stroking or poking the superior and medial (inner) part
of the thigh - regardless of the direction of stroke. The normal response is an
immediate contraction of the cremaster muscle that pulls up the testis ipsilaterally
(on the same side of the body).
▪ Testis is often elevated or lying transversely.
Strangulated Hernia: Hernias are not uncommon in military personnel and may
develop over the course of a deployment, often without the individual being aware of
the problem or dismissing the pain as a groin strain.

A strangulated hernia occurs when the hernia (A hernia occurs when an internal part of
the body pushes through a weakness in the muscle or surrounding tissue wall) contents
are ischemic due to a compromised blood supply. This phenomenon occurs most
commonly when there is a small opening in the musculature and a significant quantity of
contents within the hernia itself.

Painful, swelling in scrotum or abdominal wall that cannot be got above, irreducible,
may have peritonitis.

Bold common in military personnel:

▪ Appendicitis
▪ Ectopic pregnancy
▪ Ruptured aortic aneurysm
▪ Peritonitis
▪ Pyelonephritis
▪ Testicular torsion
▪ Bowel obstruction
▪ Renal colic
Cardiac monitoring and rhythm recognition:

Monitoring leads:
▪ 3-lead system approximates to I, II, III

▪ Color coded

▪ Remove hair

▪ Apply over bone

▪ Lead setting (II) on ECG

▪ Set gain to appropriate level

Defib paddles:

▪ Suitable for "quick look"
 ▪ Movement artefact

▪ Risk of spurious asystole

▪ Most defibrillators no longer have paddles

Adhesive monitoring electrodes:

▪ "Hands-free" monitoring and defibrillation

▪ Remember to set to "pads" on defibrillator

▪ Pacing will require both pads and 3 lead connected

▪ Synchronized DC shocks only required pads to be connected

▪ Automated External Defibrillators (AEDs) may provide a readable
rhythm strip or may simply provide an interpretation of the rhythm

ECG:

Records rhythm, rate and electrical activity of the heart.
P Wave: Caused by atrial depolarization (atria contract) initiated by the SA Node.

▪ Normal Rhythm: A normal P wave indicates healthy atrial depolarization and
proper function of the SA node.
▪ Abnormalities: Abnormalities in the P wave or atrial depolarization can indicate
conditions such as atrial enlargement, atrial fibrillation, or other arrhythmias.

PR: Atrial depolarization is complete. It represents the time it takes for electrical
impulses to travel from the atria through the atrioventricular (AV) node and into the
ventricles. It is measured from the beginning of the P wave (the start of atrial
depolarization) to the beginning of the QRS complex (the start of ventricular
depolarization).

Normal Range: The normal duration of the PR interval is typically between 120 to 200
milliseconds (0.12 to 0.20 seconds). This indicates normal conduction through the AV
node.

▪ Short PR Interval: A PR interval shorter than 120 milliseconds may suggest
conditions such as:
Wolff-Parkinson-White (WPW) syndrome: An accessory pathway that
allows for faster conduction.
Lown-Ganong-Levine (LGL) syndrome: Another type of pre-excitation
syndrome.

▪ Prolonged PR Interval: A PR interval longer than 200 milliseconds indicates
delayed conduction through the AV node, which can be seen in:
First-degree AV block: A consistent prolongation of the PR interval.
 Second-degree AV block: Some impulses are dropped, leading to
intermittent prolongation.
Third-degree AV block: Complete dissociation between atrial and
ventricular activity.

QRS: Caused by ventricular depolarization which is the electrical activation of the
ventricles leading to their contraction. It is measured from the beginning of the Q
wave to the end of the S wave and typically reflects the time it takes for the
electrical impulse to spread through the ventricles (80 to 100 milliseconds (0.08 to
0.10 seconds).
▪ Normal QRS Complex: A normal QRS interval indicates proper conduction of
electrical impulses through the ventricles, usually through the normal conduction
pathway (His-Purkinje system).

▪ Wide QRS Complex: A QRS interval longer than 100 milliseconds may indicate:
Bundle Branch Block: A delay in conduction in one of the bundle branches.
Ventricular Hypertrophy: Enlargement of the ventricular muscle.
Myocardial Infarction: Areas of dead heart muscle can alter conduction.
Electrolyte Imbalance: Such as hyperkalemia or hypocalcemia.
Ventricular Rhythm: Such as ventricular tachycardia.

▪ Narrow QRS Complex: A QRS interval shorter than 80 milliseconds may suggest:
Supraventricular Rhythms: Such as atrial fibrillation with rapid ventricular
response.
Pre-excitation Syndromes: Such as Wolff-Parkinson-White (WPW)
syndrome.
The ST interval represents the period between the end of ventricular depolarization and
the beginning of ventricular repolarization (process by which the ventricles of the heart
recover from depolarization after contraction). It is measured from the end of the S wave
to the beginning of the T wave.

▪ The normal duration of the ST segment is typically 0.08 to 0.12 seconds (80 to 120
milliseconds). However, the duration may vary slightly depending on the heart rate.

▪ Normal ST Segment: A normal ST segment is typically flat (isoelectric – on the line)
and indicates that the ventricles are in a resting state before repolarization.

▪ Elevated ST Segment: An elevated ST segment may indicate:
a. ST-Elevation Myocardial Infarction (STEMI): This is a critical condition
where there is an acute blockage of blood flow to the heart muscle, causing
damage.
b. Pericarditis: Inflammation of the pericardium can cause ST segment
elevation.
c. Early Repolarization: Commonly seen in young athletes, it can sometimes be
mistaken for pathology.

▪ Depressed ST Segment: A depressed ST segment may suggest:
a. Ischemia: Insufficient blood flow to the heart muscle, often seen during
episodes of angina.
b. Myocardial Infarction: Ischemia associated with a prior infarction.
c. Electrolyte Imbalances: Such as hypokalemia.

T wave: represents the repolarization of the ventricles, the process by which the heart's
lower chambers return to their resting state after contraction.

▪ Duration: The T wave duration is generally less than 0.2 seconds (200 milliseconds).
▪ Amplitude: The height can vary, but it is generally smaller than that of the QRS
complex.

Abnormal T Waves: Changes in the morphology of the T wave can indicate various cardiac
conditions:

▪ Inverted T Waves (Upside down): Often suggest myocardial ischemia, especially if
they occur in the leads corresponding to the affected area of the heart.
 ▪ Peaked T Waves (tall): Commonly associated with hyperkalemia (elevated
potassium levels), indicating potential cardiac instability.
▪ Flattened T Waves: May indicate hypokalemia (low potassium levels) or other
electrolyte imbalances.

▪ T Wave Changes in Other Conditions:
Ventricular Hypertrophy: May cause tall, peaked T waves.
Pericarditis: May lead to widespread ST elevation and altered T wave morphology.
Myocardial Infarction: The T wave may become flattened or inverted as ischemia
develops.

Cardiac Arrest Rhythms:

VF Bizarre irregular waveform
No recognizable QRS
complexes
Random frequency and
amplitude
Uncoordinated electrical
activity
Coarse/Fine based on
amplitude
Exclude artefact –
movement / electrical
interference
 Pulseless Ventricular Monomorphic VT:
Tachycardia: Monomorphic ventricular
tachycardia is an irregular
heart rhythm where part of
your heart beats too fast.
Broad Complex rhythm
Rapid rate
Constant QRS morphology

Polymorphic VT:
Torsade de pointes

Asystole Absent ventricular (QRS)
Activity
Atrial Activity (P Wave) may
persist
Rarely a straight-line trace
Consider fine VF
Non-Shockable

PEA Clinical features of cardiac
arrest
Bizarre complexes hard to
interpret
Often slow or irregular when
they are sometimes termed
an agonal rhythm
Non-shockable

How to read a rhythm strip:

Hemodynamic consequences of a rhythm will vary – Treat patient not the rhythm

Normally use lead 2

1. Calculate ventricular rate (QRS)
To calculate:
If regular: 300 divide by number of large squares between adjacent R waves
If irregular: Number of R waves within 30 large squares and multiply by 10

2. Assess is the QRS rhythm regular or irregular

This may be unclear at rapid heart rates, compare R-R Intervals, irregularly irregular = AF

You can mark a piece of paper with several consecutive R waves on then move along and
see if it matches. See if pattern to irregularity or if it is truly irregularity

Causes of regular rhythm

▪ NSR
▪ Sinus tachycardia
▪ Sinus bradycardia
▪ Supraventricular tachycardia
▪ Atrial flutter
Causes of irregular rhythm

▪ Sinus arrhythmia
▪ Ectopic beats
▪ Pauses & blocks
▪ Atrial fibrillation
▪ Atrial flutter with variable block

3. Decide is the QRS width prolonged or normal:

0.12
seconds) is generally assumed to be ventricular unless proven otherwise.
 Common Causes:
 Ventricular Tachycardia (VT).
 Ventricular Escape Rhythm.
 Exceptions: Conditions like bundle branch blocks or Wolff-Parkinson-
White syndrome may also cause broad QRS complexes.

5. Atrial Activity and Its Relationship to Ventricular Activity

1. Consistent Fixed PR Interval:
a. Indicates normal conduction from atria to ventricles.
b. Each P wave is followed by a QRS complex.
c. Example: Normal sinus rhythm.
2. Variable but Recognizable Pattern:
 a. Shows fluctuations in conduction time.
b. Can indicate conditions like Wenckebach (type I second-degree AV
block) or atrial flutter with variable conduction.
3. No Relationship – Atrioventricular Dissociation:
a. Indicates complete disconnect between atrial and ventricular activity.
b. P waves occur independently of QRS complexes.
c. Example: Complete heart block (third-degree AV block).

Broad Complex Tachycardia

Assumed Ventricular Origin: Broad complex tachycardia (QRS duration > 0.12
seconds) is generally assumed to be ventricular unless proven otherwise.
o Common Causes:
▪ Ventricular Tachycardia (VT).
▪ Ventricular Escape Rhythm.
o Exceptions: Conditions like bundle branch blocks or Wolff-Parkinson-
White syndrome may also cause broad QRS complexes.

Heart block:

Types of Heart Block

First Degree Heart Block:

a. Characterized by a constant, abnormally prolonged PR interval
between the P wave and the QRS complex.
b. Indicates delayed conduction through the AV node, but every atrial
impulse is conducted to the ventricles.

Second Degree Heart Block:
 c. Mobitz Type I (Wenckebach):
i. PR interval gradually increases until a QRS complex is dropped.
ii. This pattern repeats in cycles.
d. Mobitz Type II:
i. Consistently missed QRS complexes without a progressive
increase in the PR interval.
ii. More serious than Type I, can progress to complete heart block.

Third Degree Heart Block (Complete Heart Block):

e. Total electrical dissociation between the atria and ventricles.
f. Atria and ventricles beat independently, resulting in a lack of correlation
between P waves and QRS complexes.
Initial Actions in PHEC Cardiac Arrest

The initial actions during a Prehospital Emergency Care (PHEC) cardiac arrest can be
organized as follows:

1. High-Quality Chest Compressions (Right Side):
a. Ensure compressions are performed with minimal interruption.
b. Maintain adequate rate (100-120 compressions per minute) and depth (at
least 2 inches for adults).
2. Monitoring/Defibrillation (Left Side):
a. Continuously monitor the patient’s rhythm.
 b. Administer defibrillation if indicated, especially for shockable rhythms (e.g.,
ventricular fibrillation, pulseless ventricular tachycardia).
3. Airway Management (Head):
a. Establish and maintain a clear airway.
b. Consider using adjuncts such as bag-mask ventilation or advanced airway
devices as needed.
4. IV Access/Drugs (Right Side):
a. Establish intravenous access to administer medications as per protocol.
b. Administer drugs like epinephrine and amiodarone, depending on the rhythm
and clinical guidelines.

Movement Considerations

In most cases, casualties should not be moved until return of spontaneous
circulation (ROSC) is achieved.
Exceptions:
o Pediatrics: Special considerations for moving children based on specific
protocols.
o Tactical Situation: If the scene is unsafe, movement may be necessary.
o Persistent VF/PVT: Cases that do not respond to defibrillation may require
transport to an advanced care facility.
o Special protocols may apply to hypothermic patients, including potential
adjustments in resuscitation efforts.

Additional help in UK PHEC:
Prolonged Cardiac Arrests

In certain circumstances, cardiac arrest may be prolonged, and specific
considerations should be made to optimize outcomes. Early activation of critical
care teams is advisable in these cases. The following situations are likely to result
in prolonged resuscitation efforts:

1. Post-Thrombosis for Pulmonary Embolism:
a. Patients may require extended resuscitation efforts due to the complex
nature of the condition and potential for successful intervention.
2. Pregnancy:
a. Cardiac arrest in pregnant patients may necessitate specialized
protocols (e.g., left uterine displacement) and consideration of maternal
and fetal outcomes.
3. Pediatrics:
a. Pediatric patients may have different resuscitation needs and potential
for recovery, requiring specialized pediatric protocols and expertise.
4. Hypothermia:
a. Hypothermic patients can exhibit prolonged cardiac arrest due to a
slowed metabolic rate; careful resuscitation efforts should continue until
rewarming is achieved.
5. Post-Poisoning:
a. Cardiac arrest resulting from poisoning may require prolonged
resuscitation, especially if the toxin is reversible or if antidotes are
available.
6. Healthy Young Patients:
a. Young, healthy individuals may have a better chance of recovery;
resuscitation efforts should be continued longer than in older or more
comorbid populations.
Asthma:

Cardiac arrest in asthma patients often occurs after a period of hypoxemia linked to
several critical factors:

1. Severe Bronchospasm and Mucous Plugging:
a. Airway obstruction can lead to hypoxia, increasing the risk of cardiac
arrest.
2. Cardiac Arrhythmias:
a. Arrhythmias may arise due to hypoxia, stimulant drugs, or electrolyte
abnormalities, contributing to cardiac arrest.
3. Hyperinflation:
a. Air trapping and breath stacking due to hyperinflation can further
compromise ventilation and oxygenation.
4. Tension Pneumothorax:
a. This condition can occur in asthma patients and is a life-threatening
emergency that needs prompt recognition and intervention.

Ventilation Challenges

Increased Airway Resistance: Ventilation may be difficult due to bronchospasm
and increased resistance; therefore, gastric inflation should be avoided to
reduce the risk of aspiration and further complicate ventilation.

Management Strategies

▪ Early Intubation: Intubate the trachea early to secure the airway and facilitate
effective ventilation.
▪ Recommended Respiratory Rate: Maintain a respiratory rate of 10 breaths
per minute during ventilation to optimize gas exchange without over-inflating the
lungs.
▪ Dynamic Hyperinflation Management:
o If dynamic hyperinflation is suspected during CPR, consider:
▪ Compression of the Chest Wall: This can help reduce
intrathoracic pressure.
▪ Disconnection of the Tracheal Tube: This may relieve gas
trapping, improving ventilation.
Tension Pneumothorax Considerations

▪ Difficult Diagnosis: Tension pneumothorax can be challenging to diagnose in
asthma patients. Consider the possibility of bilateral tension pneumothoraxes,
especially if there is significant respiratory distress or hemodynamic instability.

Drowning:

▪ Most common in males 20-30.
▪ Drowning is defined as a process resulting in primary respiratory impairment
from submersion/immersion in a liquid medium. A person is prevented from
breathing air.
▪ Hypovolaemia after prolonged immersion can cause cardiovascular
collapse/arrest on removal from water - especially if person is upright.
▪ Keep person in horizontal position during and after retrieval.
▪ Give 5 initial ventilations
▪ If no response - start chest compressions in ratio of 30-2
▪ Give high-flow oxygen
▪ Give rapid IV fluid to correct hypovolemia
▪ Consider modified approach if hypothermic

Hypothermia: Hypothermia exists when body core temperature is below 35 degrees,
with severe being 30 degrees Celsius.
▪ Intervals between drug dosages should be doubled - adrenaline 6-10mins.
 ▪ If VF persists after 3 shocks, delay further attempts until core temp >30
degrees.
▪ Mechanical CPR device recommended.
▪ Blizzard heat packs recommended.

Paeds:

▪ All would need be taken to hospital if resuscitation commenced.

▪ Temptation to scoop and run, but establish BLS first including a functional airway
(iGel is preferred option).

▪ ALS interventions can be attempted enroute.

▪ Straight to IO advisable.

▪ Consider critical care team and pre-alert hospital early.

▪ Be aware that child protection reports are inevitable for those who have visited the
scene.

Pregnancy:

▪ Initially resuscitate as per ALS.

▪ Hand position may need to be higher.

▪ Manual displacement of uterus (easier) or left lateral tilt during CPR.

▪ IV/IO access above the level of the diaphragm.

▪ Peri-mortem C Section within 5 mins if >20/40 gestation and possible (critical
care team).

▪ Early transport to ED at hospital with obstetric cover after 4 minutes of ALS.
PE:

▪ A potential reversible cause if thrombolysis delivered by specialist teams
(4Hs/4Ts).
▪ Suggested by history (immobility, recent surgery, oral contraceptive pill, young
patient).
▪ Also suggested by signs of DVT, collapse with SOB and chest pain.
▪ Manage as per ALS.
▪ Critical care teams can deliver thrombolysis and mechanical CPR devices to
scene. Alteplase (tPA): Tissue plasminogen activator.
▪ Tenecteplase (TNK-tPA): A more modern, weight-based thrombolytic.
▪ If this is used, then CPR should continue for up to one hour and mechanical
CPR devices are often employed to assist with this.

Traumatic Cardiac Arrest:

Traumatic Cardiac Arrest has high mortality, but when ROSC is achieved, neurological
outcome in survivors appears to be better than in other causes.

Causes of cardiac arrest include - traumatic brain injury, hypovolemia, hypoxia, direct
injury to organs or major vessels, tension pneumothorax, cardiac tamponade.

Damage control resuscitation is required and is time critical.

Other:

▪ Hanging - ALS

▪ Electrocution - ALS + fluids

▪ Persistent VF/pulseless VT - transport with ongoing ALS to hospital with PCI
capability.

▪ Post-cardiac surgery - ALS and consider emergency thoracotomy (critical care
team).
 ▪ Poisoning:
ALS and consider Naloxone if opiates.
Critical Care team or transport to ED.

Post ROSC Care and ACS: 24% of Cardiac arrest get ROSC and reached
admission to hospital. Only 8/5% Survive past 30 days.

Post cardiac Arrest Syndrome: Caused by whole-body ischemia (Less than
normal blood flow) followed by reperfusion. It has a high mortality rate in patients
who initially achieve ROSC after cardiac arrest.

4 components of post-cardiac arrest syndrome:
▪ Post-cardiac arrest brain injury
▪ Post-Cardiac arrest myocardial dysfunction
▪ Systemic ischemia/reperfusion response
▪ The pathological process that caused the cardiac arrest.

Pre-Hospital Post ROSC Management: Do everything possible to prevent
pre-arrest.

Support physiology
Treat reversible causes
Transport to appropriate destination

Consider the following:
Critical care resources: Post-ROSC PHEA for agitated patients, blood
products, additional drugs, ultrasound, surgical capability (relief of
tamponade), mechanical CPR.

POST ROSC:

Examples of vasopressors and inotropes include:

▪ Vasopressors: These drugs increase vascular tone and blood pressure by
constricting blood vessels:
o Phenylephrine: Causes peripheral vasoconstriction and increases arterial
pressure
o Norepinephrine: A vasoconstrictive sympathomimetic that raises blood
pressure
o Epinephrine: A vasoconstrictive sympathomimetic that raises blood
pressure
o Vasopressin: A vasopressor drug
o Terlipressin: A vasopressor drug
 ▪ Inotropes: These drugs increase myocardial contractility, which can affect heart
rate, blood pressure, and other factors:
o Dobutamine: A synthetic catecholamine that increases cardiac output
o Levosimendan: A calcium sensitizer that increases contractility without
increasing cAMP levels
o Milrinone: An inotrope
o Enoximone: An inotrope

Diagnosis:
Reversible Pathology and their management:

1. STEMI (ST-Elevation Myocardial Infarction):
a. Management:
i. Thrombolysis: Administer thrombolytic agents to dissolve the clot.
ii. PCI (Percutaneous Coronary Intervention): Perform angioplasty
and stenting to restore blood flow.
2. Massive Pulmonary Embolism:
a. Management:
i. Thrombolysis: Use thrombolytic therapy to dissolve the embolus
and restore pulmonary blood flow.
3. Hypovolemia:
a. Management:
i. Fluid/Blood Resuscitation: Administer IV fluids and/or blood
products to restore circulating volume.
4. Hypothermia:
a. Management:
i. Rewarming: Use active warming techniques (e.g., blankets,
heating devices) to raise the patient’s core temperature.
 5. Hypoglycemia:
a. Management:
i. Glucose Administration: Administer oral glucose or IV dextrose to
raise blood sugar levels.
6. Hyperkalemia:
a. Management:
i. Calcium Administration: Administer calcium gluconate or calcium
chloride to stabilize cardiac membranes and protect against
arrhythmias.
7. Cardiac Tamponade:
a. Management:
i. Drainage: Perform pericardiocentesis or surgical drainage to
relieve pressure on the heart.
8. Tension Pneumothorax:
a. Management:
i. Decompression: Perform needle decompression (e.g., using a
large-bore cannula) to relieve intrathoracic pressure.
ii. Higher risk if asthma
9. Poisoning:
a. Management:
i. Antidote Administration: Administer specific antidotes based on
the type of poison (e.g., naloxone for opioid overdose, activated
charcoal for certain ingestions, Sodium Bicarbonate with tri-cyclic
antidepressants)

Ischemic Heart Disease:

Appropriate recognition and treatment may prevent arrest. Post-arrest patients will
benefit from transfer to specialist centres with PCI, device implantation and specialist
rhythm management. Refractory VF should be transported to a PCI capable facility
with CPR ongoing (critical care team can assist with additional drugs and mechanical
CPR). Adults who are unconscious after cardiac arrest caused by suspected acute
STEMI are not excluded from having coronary angiography (with follow-on primary
percutaneous coronary intervention (PCI) if indicated).
Differential Diagnosis in Chest Pain that can cause arrest:

1. Acute Coronary Syndrome (ACS) ACS, including heart attacks, blocks blood flow to
the heart, causing ischemia. This can trigger arrhythmias (like ventricular fibrillation) or
heart failure, leading to cardiac arrest.

2. Pulmonary Embolism (PE) A large blood clot in the lungs strains the right heart,
causing right heart failure, severe hypoxemia, and obstructive shock. This can lead
to arrhythmias and cardiac arrest.

3. Aortic Dissection A tear in the aorta can lead to rupture, cardiac tamponade, or
blockage of coronary arteries. These result in internal bleeding, obstructive shock, or
arrhythmias, causing cardiac arrest.

Acute Coronary Syndromes (ACS)

Is a term that encompasses a range of conditions associated with sudden reduced blood
flow to the heart muscle, primarily due to the rupture of atherosclerotic plaques and the
formation of blood clots in the coronary arteries

1. ST-Segment Elevation Myocardial Infarction (STEMI)

Diagnosis:
o ST Segment Elevation: Identified on a 12-lead ECG.
o New-Onset Left Bundle Branch Block (LBBB): May also indicate STEMI.
Management:
o Administer ACS medications (e.g., antiplatelets, anticoagulants, nitrates).4
Antiplatelet reducing the risk of clot formation.
Aspirin: Irreversibly inhibits cyclooxygenase-1 (COX-1), decreasing
thromboxane A2 production.
P2Y12 Inhibitors:
Clopidogrel (Plavix): Blocks the P2Y12 receptor on platelets, preventing
aggregation.
Prasugrel (Effient): Similar to clopidogrel but with a more potent effect on
platelets.
 Anticoagulants: prevent blood clots from forming or growing larger by
interfering with clotting factors.
Unfractionated Heparin (UFH): Activates antithrombin, inhibiting thrombin
and Factor Xa.
Low Molecular Weight Heparins (LMWH):
Enoxaparin (Lovenox): Inhibits Factor Xa more selectively.
Direct Oral Anticoagulants (DOACs):
Rivaroxaban (Xarelto) and Apixaban (Eliquis): Direct Factor Xa inhibitors.
Nitrates: These drugs dilate blood vessels, reducing the heart's oxygen
demand and alleviating chest pain.
Nitroglycerin: Available in sublingual, oral, or IV forms for rapid relief of
chest pain.
Isosorbide Dinitrate: Longer-acting oral nitrate for ongoing angina
management.

Time-Critical Transfer: Transport to a facility with PPCI (Primary Percutaneous
Coronary Intervention) capability.
PPCI: A procedure to open the blocked coronary artery.
Consider thrombolysis if PPCI is not available in a timely manner.

2. Non-ST-Segment Elevation Myocardial Infarction (NSTEMI)

Diagnosis:
o Clinical history consistent with ACS.
o ECG Findings: May show non-ST elevation ischemic changes or be normal.
Management:
o Administer ACS medications (e.g., antiplatelets, anticoagulants).
o Time-Critical Transfer: Transfer to a facility for further evaluation and
management.

3. Unstable Angina (UA)

Diagnosis:
o Cardiac chest pain occurring at rest or with minimal exertion.
o ECG Findings: May show transient changes or be normal.
Management:
o Administer ACS medications (e.g., antiplatelets, nitrates).
 o Time-Critical Transfer: Transfer for further assessment and management.

Clinical History in ACS:

▪ Characteristics:
o Location: Pain typically occurs in the chest, often radiating to the arms
(especially the left arm), back, neck, jaw, or epigastric area.
o Duration: Usually lasts longer than 15 minutes; may be persistent or
intermittent.
o Nature: Described as pressure, squeezing, tightness, or a burning
sensation.
▪ Associated Symptoms:
o Nausea and vomiting.
o Diaphoresis (excessive sweating).
o Dyspnea (shortness of breath).
o Palpitations or irregular heartbeats.
o Hemodynamic instability: Possible signs include hypotension,
tachycardia, or altered mental status.

Atypical Presentations

▪ Certain populations may present atypically with ACS symptoms, which can
complicate diagnosis:
▪ Women:
o It is more likely to report atypical symptoms such as fatigue, shortness of
breath, nausea, and abdominal pain rather than classic chest pain.
▪ Diabetics:
o May experience silent ischemia or atypical symptoms due to neuropathy,
leading to diminished pain perception.
▪ Older Patients:
o Often present with vague symptoms like confusion, weakness, or fatigue
instead of classic angina, making it challenging to recognize ACS.
Pre-Hospital Management of Acute Coronary Syndrome (ACS):
MONA

MONA is an acronym that represents the key components of pre-hospital
management for patients experiencing acute coronary syndrome (ACS).

Drugs

1. Morphine:
a. Dosage: Administer 2.5–10 mg IV. Every 5-15 minutes.
b. Repeat: Can repeat to a total of 20 mg if needed for pain relief.
c. Indication: Provides analgesia and may help reduce myocardial
oxygen demand.
2. Oxygen:
a. Target: Titrate oxygen to maintain SaO2 > 94%.
b. Supplemental Oxygen: Administer if SaO2 is below 94%.
c. Considerations: For patients with known or suspected COPD, aim for an
SaO2 of 88-92% to avoid the risk of hypercapnic respiratory failure.

3. Nitrates (Glyceryl Tri-Nitrate, GTN):
a. Administration: Available as a spray or tablet.
b. Dosage: Repeat every 5–10 minutes if chest pain persists and blood
pressure is >90 mmHg systolic.
c. Cautions: Do not administer if the patient has low blood pressure, as
this can worsen right-sided heart function and compromise preload.

4. Antiplatelet Medication:
a. Aspirin: Administer 300 mg PO for immediate antiplatelet effect.
b. Clopidogrel:
i. 300 mg PO as an adjunct to thrombolysis.
 ii. 600 mg PO as an adjunct to PPCI (Primary Percutaneous
Coronary Intervention).

Discharge at Scene Pathway:

The discharge at scene pathway is akin to military protocols for transferring patients,
specifically to a Role 1 facility, while avoiding higher-level care facilities (Role 2 or 3).

Spinal Injury Considerations
Hospital Transfer:
All patients suspected of having a spinal injury should be transported to the
hospital.

NEXUS Criteria

The NEXUS (National Emergency X-Radiography Utilisation Study) criteria help
determine whether trauma patients require cervical spine imaging. Patients who do not
require imaging must meet all the following criteria:

1. Alert and stable: The patient is conscious and hemodynamically stable.
2. No focal neurologic deficit: Absence of weakness, numbness, or other
neurological signs.
3. No altered level of consciousness: The patient is fully aware and oriented.
4. Not intoxicated: The patient does not have a significant level of alcohol or drug
intoxication.
5. No midline spinal tenderness: No tenderness along the spine when palpated.
6. No distracting injury: No other injuries that may distract from a potential spinal
injury.

JRCALC Modifications

The JRCALC (Joint Royal Colleges Ambulance Liaison Committee) guidelines modify
NEXUS to include an additional criterion:
 Patient complaint of spinal pain: If the patient reports pain in the spinal region,
imaging is indicated.

Canadian C-Spine Rule

Recommendation: The Canadian C-spine rule is favored by the National Institute
of Clinical Excellence (NICE) for assessing the need for cervical spine imaging.
Sensitivity: It has shown over 99% sensitivity in detecting significant cervical spine
injuries during initial in-hospital studies.

Concerns About Fractures:
If there are any concerns regarding potential thoracic or lumbar fractures,
immobilization is essential.

JRCALC Recommendations

Full Immobilization:
o Collar and Blocks: The Joint Royal Colleges Ambulance Liaison
Committee (JRCALC) recommends full immobilization, including the use of
a cervical collar and spinal blocks, when there is suspicion of thoracic or
lumbar injury.
Self Extrication in Cervical Injuries:
o For patients with suspected cervical injuries who are alert and have no
distracting injuries, they may self-extricate from vehicles if possible. This
should be done before lying down on a trolley for immobilization.
Head Injury Management

Criteria for Referral to Hospital:

Patients with head injuries should be referred to a hospital if any of the
following criteria are met:

Medical History

Previous Brain Surgery: History of prior surgeries on the brain.
Bleeding or Clotting Disorders: Any history indicating issues with
blood coagulation.

Type of Injury

High-Energy Head Injury: Involvement of significant force or trauma.
 Complex Skull Fracture: Any suspicion of complex fractures of the
skull.
Penetrating Injury: Evidence of objects penetrating the skull.
Consciousness Level: Unconsciousness or lack of full consciousness
following the injury.

Symptoms Following Injury

New Focal Neurological Deficits: Any loss of function or ability
related to specific body areas.
Seizures: Any seizure activity since the time of injury.
Persistent Headache: Continuous headache that began after the
injury.
Amnesia: Inability to recall events before or after the injury.
Vomiting Episodes: Any occurrences of vomiting since the injury.
Irritability or Altered Behavior: Notable changes in mood or
behavior.

Other Considerations

Anticoagulant or Antiplatelet Treatment: Current use of
anticoagulants or antiplatelet medications (excluding aspirin).
Drug or Alcohol Intoxication: Current impairment due to substance
use.
Safeguarding Concerns: Issues related to the patient’s safety or
welfare.
Professional Staff Concerns: Any concerns raised by healthcare
professionals regarding the patient's condition.
Focal Neurological Deficit

Definition:

Focal neurological deficits are problems restricted to specific areas or
functions, which may include:

Difficulties with understanding, speaking, reading, or writing.
Decreased sensation or altered sensation in specific body parts.
Loss of balance or coordination.
General weakness in limbs or other areas.
Visual changes, such as blurred or double vision.
Abnormal reflexes or issues with walking.

High-Energy Head Injury

Characteristics:

High-energy head injuries are typically associated with significant trauma
and can lead to a range of neurological deficits similar to those outlined
above.

Limb Injuries: Clinical Rules for Discharge

Clinical Rules: The Ottawa Ankle and Knee Rules help determine the need
for imaging and facilitate appropriate discharge pathways, such as to
minor injury units.
Ottawa Ankle Rules

The Ottawa Ankle Rules are designed to rule out clinically significant foot
and ankle fractures and reduce unnecessary X-ray imaging. The criteria
include:

X-ray is required if any of the following are present:
o Bone tenderness at any of the following locations:
▪ Posterior edge or tip of the lateral malleolus (outer ankle
bone).
▪ Posterior edge or tip of the medial malleolus (inner ankle
bone).
o Inability to bear weight both immediately after the injury and
during the examination (i.e., cannot take four steps).

Ottawa Knee Rules

The Ottawa Knee Rules help determine the necessity of X-ray imaging for
knee injuries. X-rays are indicated if any of the following criteria are met:

Age: Patient is 55 years or older.
Tenderness:
o Tenderness at the head of the fibula.
o Isolated tenderness of the patella (kneecap).
Inability to flex the knee:
o Patient cannot flex the knee greater than 90 degrees.
Inability to bear weight:
o Inability to bear weight both immediately after the injury and
during the examination (i.e., cannot take four steps).
Drowning: Submersion and Immersion

Drowning is defined as a process that results in primary respiratory
impairment due to submersion in a liquid medium.
 Submersion: Occurs when the head goes below the liquid.
Immersion: The body enters the liquid while the head remains above
it, although water may still be aspirated or ingested.

Key Facts

Many drowning incidents happen within a few meters of safety, often
involving victims who are otherwise healthy and physically capable.
Proposed mechanisms for drowning include:
o Cold Shock
o Exhaustion ("swim failure")
o Hypothermia

Cold Shock

Cold Shock encompasses both respiratory and cardiovascular effects that
can lead to rapid incapacitation upon sudden immersion in cold water
(typically below 15°C).

Respiratory Effects

Rapid, Uncontrollable Breathing: This can lead to water aspiration.
Hyperventilation: May result in muscle weakness and
incapacitation.

Cardiovascular Effects

Sympathetic Nervous System Response: The "fight or flight"
response can elevate heart rate and blood pressure.
Potential Complications: This can precipitate:
 o Cardiac arrhythmias
o Myocardial ischemia
o Cerebrovascular accidents (strokes)

Timing: Cold shock is most critical in the first 3 minutes of immersion, after
which the effects of cold fatigue may begin to manifest, potentially leading
to hypothermia.

Mammalian Diving Response (MDR)

The Mammalian Diving Response is triggered when the face or
oropharynx is exposed to cold water. This response involves:

Slowing of the Heart Rate: Driven by the parasympathetic nervous
system.
Autonomic Conflict: Simultaneous activation of the sympathetic and
parasympathetic nervous systems can lead to fatal arrhythmias,
even in healthy individuals.

Exhaustion and Hypothermia

Swim Failure:

▪ Prior to hypothermia, conditions like shivering and muscle stiffness
can impair swimming ability, often termed "swim failure." This is
particularly evident in individuals with significant skin exposure to
cold water.
Why Drowning Can Be Fatal

Hypoxia:

▪ The primary clinical concern in drowning incidents is hypoxia.
▪ Aspiration of Fluid: Water entering the lungs leads to respiratory
impairment. If severe or prolonged, this can result in cardiac arrest.
▪ Early Intervention: Rapid action to alleviate hypoxia is crucial for
improving survival chances.

Freshwater vs. Saltwater Drowning

▪ Freshwater Drowning:
o Destroys lung surfactant.
o Causes rapid fluid movement into circulation, leading to
hemodilution and alveolar collapse.
▪ Saltwater Drowning:
o Draws water into the lungs, causing greater alveolar fluid
accumulation and cardiovascular collapse.
o Has a lesser effect on surfactant compared to freshwater.

Note: Treatment approaches are the same for both types of drowning.

Complications of Submersion and Immersion

1. Hypothermia:
a. Considered in all cases, as it can mimic death signs.
b. Protective effects can occur (e.g., reduced oxygen
consumption with lower core temperatures), particularly in
children.
 c. Milder hypothermia may provoke cardiac arrhythmias upon
rewarming.
2. Injuries:
a. Always assess for head and spinal injuries, especially in cases
involving diving into shallow water.
b. Injuries may be either a consequence of the drowning event or
a contributing factor.
3. Post-Immersion Circulatory Collapse:
a. Victims often float vertically in water, leading to increased
pressure on the legs.
b. Vasoconstriction from cold water results in hypovolemia due
to increased urinary output.
c. Upon rescue, loss of pressure combined with warming can lead
to life-threatening cardiovascular collapse.
d. Recommendation: Keep the patient flat during rescue to
mitigate risks.
4. Respiratory Complications:
a. Potential outcomes include respiratory distress, pulmonary
edema, and infection.
b. Recognize that respiratory function may deteriorate in the
hours following a near-drowning incident, potentially leading
to ARDS or pneumonia.
c. Treatment: Administer high-flow oxygen and address
bronchospasm with nebulized salbutamol.

Prognosis

Immersed Victims: Generally, have a better prognosis compared to
submerged victims.
Scene Management Considerations

Resuscitation Guidelines:
o Submersion for 90 minutes: Resuscitation is warranted if the
water temperature is below 6°C or if a child is involved.
o Good Outcomes: Occasionally observed in small children after
prolonged submersion, especially in cold water.
Clinical Management of Drowning Victims

Assess A-E (Airway, Breathing, Circulation):

Airway Management

Clear Airway: Ensure the airway is clear and free from obstruction.
 Suction Ready: Maintain suction at hand due to the high risk of regurgitation.

Ventilation

Importance: Adequate ventilation and oxygenation are crucial for restoring cardiac
activity.
Assisted Ventilation: Consider assisted ventilation if:
o SPO2 < 90%
o Respiratory rate (RR) < 12 or > 30
o Inadequate lung expansion based on the patient's consciousness level.
Challenges: Ventilation may be difficult due to reduced lung compliance if water has
been inhaled. Even with large volumes of water, the lungs can still be ventilated.

Cardiac Arrest Protocol

Inflation Breaths: If the patient is in cardiac arrest, administer 5 inflation breaths
before commencing CPR.

Oxygen Administration

Oxygen for All: Administer oxygen to all patients initially, as SPO2 readings may be
inaccurate due to cold peripheries. Compression-only CPR is inadequate without
oxygen.

Monitoring

Cardiac Arrhythmias: Monitor closely, as hypothermia can lead to very slow or
undetectable heart rates.
ECG: Perform a 12-lead ECG to assess cardiac function.

CPR

Compressions: Begin compressions when on a firm surface and appropriate for age.
Response: Bradycardia often improves with better ventilation and oxygenation. Be
aware that hypothermia may cause cardiac dysrhythmias.
Concomitant Injuries

Neck and Back Injuries: Always consider and treat any potential neck or back
injuries.

Warming

Warm Slowly: Avoid rapid rewarming unless the patient is in cardiac arrest.

IV Fluids

Fluid Consideration: Consider administering IV fluids if available, as prolonged
immersion may lead to hypovolemia. Do not hypotensive-resuscitate drowning
victims; follow fluid guidelines for management.

Positioning

Keep Flat: Maintain the patient in a flat position to avoid postural drainage. Note that
80% will aspirate water into the stomach, and tilting the patient can move water
back into the pharynx, further compromising the airway.

Observations

Asymptomatic Cases: Consider observing all asymptomatic near-drowning cases
for at least 6 hours.
Symptomatic Patients: Admit all symptomatic patients for further evaluation and
management.
Capnography in pre-hospital emergency care:

The end-result of cellular respiration is the waste gas Carbon Dioxide
(CO2). This is transferred in the bloodstream from the site of cellular
respiration (the mitochondria) to the lungs. In the lungs, CO2 diffuses into
the alveoli down a concentration gradient. Ventilation of the lungs results
in CO2 being expelled into the atmosphere.

ETCO2: ETCO2 may be recorded either through monitoring attached to
airway devices (such as endotracheal tubes and iGels), or through nasal
prongs for spontaneously breathing patients. Monitors record ETCO2
either simply as a number or as a constant waveform which gives us
much more information. The number is referred to as capnometry, the
graph is referred to as waveform capnography.

Normal Values of CO₂ in Respiration

Inspired Air:
o CO₂ Level: 0.04 kPa (0.3 mmHg)
Alveolar Air:
o CO₂ Level: 5.3 kPa (40 mmHg)
Expired Air:
o CO₂ Level: 3.6 kPa (27 mmHg)

ETCO₂ Readings in Different Conditions

Nasal Specs:
o Reading: 3.6 kPa
 Intubated Patients:
o Reading: 4.5 kPa to 5.5 kPa

Criteria for Sustained ETCO₂ Monitoring

To record a sustained ETCO₂, a patient must have:

An Airway (intubated or otherwise secured)
Be Ventilating (spontaneously or with assistance)
Have Functional Circulation (spontaneous circulation or during CPR)

Uses of ETCO₂ Monitoring

Confirm Tracheal Placement: Essential for verifying correct
placement of the endotracheal tube during intubation.
Confirm Ventilation: Allows for monitoring and recording the rate of
ventilation.
Measure Circulatory Adequacy: Particularly important during cardiac
arrest scenarios.

Important Considerations

Intubation Protocol: If ETCO₂ monitoring is unavailable, intubation
should not be performed.
ETCO₂ Trace During CPR: There should always be an ETCO₂ trace
during CPR when a tracheal tube is in place, even if the readings are
low.
Absence of ETCO₂: A lack of ETCO₂ suggests potential esophageal
intubation or equipment failure.

Waveforms:

Types of waveform:
Normal, Hyperventilation (falling CO2 level, higher rate), Hypoventilation
(increasing CO2 level, lower rate), Lower airway obstruction (sloping plateau,
'sharks fin'), Oesophageal intubation (rapidly falling CO2, abnormal
waveform).

Normal Waveform:

Features:
o Expiratory Upstroke: The initial rise in CO₂ during expiration.
o Expiratory Plateau: A flat phase where CO₂ remains steady.
o D = ETCO₂ Value: The peak value during expiration.
o D-E = Inspiration Begins: Transition point indicating the start of
inhalation.

Hyperventilation:
Characteristics:
o Rapid respiratory rate.
o ETCO₂ Level: Rapidly falling, indicating decreased CO₂ in
exhaled air.

Hypoventilation:

Characteristics:
 o Slower respiratory rate.
o ETCO₂ Level: Increasing due to insufficient ventilation.

Lower Airway Obstruction:

Characteristics:
o Waveform Shape: Sloping plateau or “shark fin” appearance.
o Indicates a prolonged expiratory phase due to obstruction.

Oesophageal Intubation:
Characteristics:
o Waveform: Rapid decline in ETCO₂ over several ventilations.
o Indicates potential oesophageal placement of the tube, which requires
urgent removal or confirmation of cardiac arrest.
Causes of Oesophageal Intubation

Possible Causes:
o Missed intubation attempt.
o A normal capnogram is the best indicator of proper ET tube
placement.
o When the ET tube is in the esophagus, little to no CO₂ will be
detected in the exhaled air.

Reading Waveforms: CO₂ Levels and Their Implications

Reasons for Higher Than Expected CO₂ Levels:

1. Hypoventilation:
a. Effect: Reduced respiratory rate leads to CO₂ accumulation in
the body.
2. Increased CO₂ Production:
a. Causes: Conditions that elevate metabolic activity (e.g., fever,
sepsis).
3. Reduced CO₂ Excretion:
a. Conditions:
i. COPD (chronic obstructive pulmonary disease) where
ventilation is impaired.
4. Medications:
 a. Examples: Administration of sodium bicarbonate, which can
increase blood CO₂ levels.

Reasons for Lower Than Expected CO₂ Levels:

1. Hyperventilation:
a. Effect: Increased respiratory rate causes excessive CO₂
removal (blowing off CO₂).
2. Reduced Cellular Respiration:
a. Considerations:
i. Evaluate if the heart is functioning normally.
ii. Assess if oxygen is adequately delivered to tissues.
3. Cardiac Arrest:
a. Implication: Poor quality CPR may not effectively circulate
blood, impacting CO₂ levels.

Important Note:

Total Absence of ETCO₂:
o Urgent consideration should be given to:
▪ Misplaced endotracheal tube in intubated patients.
▪ Possible equipment failure, necessitating immediate
troubleshooting.

ETCO₂ Devices

1. Easi-Cap:
a. Function: Provides a color change in the presence of CO₂.
2. EMMA:
 a. Function: Delivers continuous CO₂ measurements.
b. Features: Capable of displaying a graph, depending on the
model.
3. Monitor:
a. Type: Waveform capnography monitor (e.g., Tempus Pro).
b. Function: Offers real-time monitoring of ETCO₂ levels with
graphical representation.

Causes increased ETCO2 Causes decreased ETCO2
Respiratory Respiratory insufficency Alveolar Hyperventilation
Respiratory depression Bronchospasm
Obstructive pulmonary Mucous Plugging
disease Partial airway obstruction
Effective bronchodilator ETT in hyopharynx
therapy Pulmonary embolus
Decreased minute Increased minute
ventilation ventilation
Circulatory Increased CO with constant Cardiac arrest
ventilation Embolism
Sudden hypovolemia
Sudden hypotension
Decreased CO
Metabolism Pain Analgesia / sedation
Hyperthermia Hypothermia
Malignant Hyperthermia
Shivering
Equipment Defective exhalation valve Leak in airway system
Exhaused Co2 absorber

Iatrogenic NAHCO2 infusion
Torniquet release

Intoxication and poisoning:

Intoxication: A transient condition that follows the administration of a psychoactive
substance and results in disturbances in the level of consciousness, cognition,
perception, judgement, affect, or behavior, or other psychophysiological functions and
responses.
Intoxication: Intoxication is highly dependent on the type and dose of drug and is
influenced by an individual's level of tolerance and other factors. Frequently, a drug is
taken in order to achieve a desired degree of intoxication.

Acute intoxication: Acute intoxication is the term in ICD-11 (WHO 2019) for
intoxication of clinical significance. Complications may include trauma, inhalation of
vomitus, delirium, coma and convulsions, depending on the substance and method of
administration. Assessment of alcohol intoxication: Local policies determine treatment
protocol. A blood sugar should be obtained for anyone who appears intoxicated.

Poison: Any substance that interferes with normal bodily functions after it is
swallowed, inhaled, injected, or absorbed. The branch of medicine that deals with the
detection and treatment of poisons is known as toxicology.

Types of Poisons and Their Effects:

1. Metabolic Interference:
a. Example: Cyanide
b. Effect: Disrupts cellular respiration.
2. Organ Damage:
a. Examples: Heavy metals (e.g., lead, mercury) and paracetamol.
b. Effect: Can lead to liver or kidney damage.
3. CNS Depression:
a. Examples: Diazepam, heroin.
b. Effect: May cause coma and respiratory/circulatory failure.
4. Respiratory and Circulatory Impact:
a. Example: Carbon monoxide.
b. Effect: Affects oxygen transport and can lead to hypoxia.
5. Corrosive Agents:
a. Examples: Bleach, acids.
b. Effect: Cause tissue damage on contact.
Diagnosis and Management of Poisoning

Diagnostic Approach:

Identification Challenges: It is often difficult to positively identify the specific
poison.
Clinical Examination:
o Use the ABCDE approach (Airway, Breathing, Circulation, Disability,
Exposure) along with a glucose check.
o Essential for assessing the severity of poisoning.
Toxidromes:
o Many poisons produce distinct symptoms, known as toxidromes, which
assist in identification.

Management:

Supportive Treatment:
o Most treatments are supportive, even in intensive care settings.
Specific Antidotes:
o Some poisons have specific antidotes (e.g., naloxone for opioid
overdose).
Classification of Poisoning

1. Unintentional or Accidental Poisoning

Common Demographics:
o Most frequently seen in children under five.
o Common substances: tablets, household chemicals, and certain plants.
Older Children and Adults:
o May accidentally ingest chemicals from bottles with unclear labeling.
Statistics:
o Responsible for approximately 1000 deaths annually in the UK.
o 50% of these deaths are attributed to opiate/opioid poisoning.
Body Packers:
 o Drug smugglers who conceal drugs wrapped in condoms or latex within the
body (e.g., in the bowel, rectum, or vagina).
o Risk of fatal poisoning occurs if the package leaks.
Clinical Note:
o Always consider opiate/opioid poisoning if the relevant toxidrome is
present.

2. Deliberative Poisoning

Prevalence:
o Accounts for one-third of all acute poisoning cases.
o Typically involves intentional overdoses or substance abuse.
Common Substances:
o Paracetamol (Acetaminophen): accounts for 50% of all intentional self-
poisoning cases.
o Other common substances include non-steroidal anti-inflammatory drugs
(NSAIDs) and antidepressants.

3. Non-Accidental Poisoning

Fabricated or Induced Illnesses:
o Rare cases where a parent deliberately poisons a child.
o Always consider child protection protocols in suspected cases.
Homicidal Poisoning:
o Also rare; may involve either acute or chronic poisoning with various
chemicals.

Assessment and Management of Poisoning

Resus-RSI-DEAD Protocol

1. RESUS: Resuscitation
a. Airway: Ensure the airway is clear and patent.
b. Breathing: Assess breathing; provide support if needed.
c. Circulation: Evaluate circulatory status; perform CPR if necessary.
2. Detect and Correct:
a. Hypoglycaemia: Check blood sugar levels and treat as necessary.
 b. Seizures: Monitor for seizures; provide appropriate management.
c. Hyper/Hypothermia: Assess and manage body temperature abnormalities.
d. Emergency Antidote Administration: Administer specific antidotes if
indicated.
3. Risk Assessment:
a. Drug: Identify the substance involved.
b. Dose: Determine the amount taken.
c. Time Since Ingestion: Establish how long ago the substance was ingested.
d. Clinical Features and Course: Observe and document symptoms and their
progression.
e. Patient Factors: Consider age, weight, pre-existing conditions, and other
individual factors.

Note: If the patient is alert, they may provide information about the substance taken. Look
for discarded packets and bottles to gather additional data. Check for dispensed dates on
prescriptions, which can help assess if the medication was recently acquired.

4. UK TOXBASE:
a. Most commonly used online database for poison management.
b. Contact the National Poisons Information Service (NPIS) via the
ambulance service clinical hub in the UK for further advice.
5. Supportive Care and Monitoring:
a. Morbidity and mortality often arise from the effects of poisons on the
respiratory, cardiovascular, and central nervous systems. Supportive
treatment can range from IV fluids to intensive care unit (ICU) admission,
depending on the severity.
6. Investigations:
a. Screening: Perform a 12-lead ECG on all unconscious patients, as many
overdoses can cause significant ECG changes (e.g., bradycardia,
tachycardia, QRS prolongation, heart block, QT prolongation).
b. Paracetamol: Specific testing for paracetamol levels if suspected.
7. DEAD:
a. Decontamination:
i. Skin or clothing may need decontamination.
ii. Activated Charcoal: Used for gastrointestinal decontamination if the
patient presents within one hour of ingestion of certain poisons. The
patient must be fully conscious and able to protect their airway.
b. Enhanced Elimination:
 i. Pre-hospital: Focus on ensuring good hydration.
ii. In Medical Treatment Facility (MTF): Options include urinary
alkalinization, hemodialysis, and hemofiltration for certain
poisonings.
c. Antidotes:
i. Pre-hospital:
1. Opiates/Opioids: Naloxone
2. Cyanide: Hydroxocobalamin
3. Carbon Monoxide: High-flow oxygen
4. Nerve Agents: Combopen (atropine, pralidoxime, diazepam)
5. Tricyclic Antidepressants e.g. amitriptyline: Sodium
bicarbonate
ii. In MTF:
1. Beta Blockers: Glucagon
2. Paracetamol: N-Acetyl cysteine
3. Methemoglobinemia: Methylene blue
4. Digoxin: Digi-bind
5. Ethylene Glycol/Methanol: Ethanol or Fomepizole
6. Cyanide: Hydroxocobalamin, sodium thiosulfate, sodium
nitrite, dicobalt edetate
8. Disposition:
a. Non-intentional Exposures: May be suitable for discharge if they meet local
guidelines, including:
i. The substance is verified as harmless by TOXBASE or NPIS.
ii. A responsible adult is present to monitor the patient.
iii. The patient is advised to seek medical attention if they feel unwell.
iv. The patient’s health visitor or general practitioner (GP) is informed.

Overdose:

Always check glucose levels in overdose. Deliberate overdoses usually involve an
element of mental health or capacity issues. In general, all deliberate overdoses
will need transportation to a MTF. All unintentional overdoses should have a
mental health assessment.
Mass Poisoning: Overview and Response

Definition: Mass poisoning refers to situations where multiple individuals are
affected by a toxic substance, leading to a public health emergency.

Possible Sources of Mass Poisoning:

1. Industrial Accidents:
a. Chemical Spills: Accidental releases of hazardous chemicals in
factories or during transport can result in widespread exposure.
b. Chemical Manufacturing Plants: Explosions or leaks in facilities
producing toxic substances can endanger nearby communities.
2. Domestic Accidents:
a. Carbon Monoxide Poisoning: Often occurs due to faulty heating
systems, poorly ventilated spaces, or the use of gas appliances.
Symptoms can affect multiple household members.
3. Terrorist Attacks:
a. Use of Nerve Agents: Intentional release of chemical weapons,
such as sarin or VX, in public spaces can lead to mass casualties.
b. Biological or Chemical Warfare: Attackers may use toxins to
incapacitate or kill large numbers of people.

Symptoms of Early Poisoning:

Symptoms may mimic common conditions, such as anxiety or flu,
including:
o Nausea
o Vomiting
o Headaches
 o Dizziness
o Confusion
o Shortness of breath

Note: The overlap in symptoms can lead to misdiagnosis or delayed
treatment.

Key Indicators to Suspect Mass Poisoning:

Presence of 2 or more casualties with similar symptoms.
Rapid onset of symptoms in a community or specific area.
Exposure to a potential source, such as an industrial facility or after a
specific event (e.g., public gathering, food festival).

Safety and Response Measures:

1. Personal Safety:
a. Do Not Put Yourself at Risk: Avoid entering areas suspected to be
contaminated without proper protective equipment.
2. Call for Specialist Assistance:
a. Hazardous Area Response Teams (HART): Trained teams
equipped to handle hazardous materials incidents.
b. Chemical, Biological, Radiological, and Nuclear (CBRN) Teams:
Specialized units capable of identifying and responding to
chemical or biological threats.
3. Emergency Response:
a. Evacuation: If safe to do so, evacuate affected individuals to
minimize further exposure.
b. Decontamination: Ensure that individuals exposed to toxic
substances are decontaminated to prevent secondary
contamination.
 c. Monitoring and Treatment: Provide medical assistance to
affected individuals as soon as possible.

Major Incidents and MIMMS:

Any incident where the location, number, severity or type
of live casualties requires extraordinary resources.

These can be:
▪ Natural incidents or man-made
▪ Simple or compound
▪ Compensated or uncompensated

Nato Definition: Major Medical Incident (MMI) is an incident where the number, severity,
or type of live casualties, or by its location, requires extraordinary resources.

An MMI is declared ‘bottom up’, with each level of command considering whether it also
needs to make the same declaration.

A Mass Casualty Incident (MASCAL) is an MMI which, despite the use of extraordinary
measures, has or will result in an overwhelming of the available medical capability and/or
capacity.

Stages of a major incident:

Categories of Major Incidents:
Natural or man made

Simple or compound: A simple incident is one where infrastructure (communication
and transport) remains intact. A compound incident is one where existing infrastructure
is damaged.

Compensated or Uncompensated: A 'compensated incident' is defined as an incident
in which casualties are dealt with by mobilising additional resources. An
'uncompensated incident' is when medical resources are unable to cope with the
number of casualties, despite mobilising additional resources.

Structural approach to major incident management:

CSCATTT

▪ Command and control:
▪ The first vehicle on scene will become the Incident
Commander until relieved
▪ Action cards are issued
▪ Tabards worn

▪ Safety: Ensure your own safety
▪ Ensure scene safety using cordons

▪ Communications: Start early communications with
METHANE
▪ Use Airwave and Talk Groups
▪ Start a log

▪ Assessment: Assess the incident
▪ Use METHANE to request resources to the Ambulance
Control Room Manager as soon as you can

▪ Triage: Start Primary Triage
▪ Encourage casualty self-help
▪ Establish a Casualty Clearing Station

▪ Treatment: Start treatment/stabilization as soon as the sieve
is complete
 ▪ Transport: Consider the capability, availability and suitability
of types of transport
▪ Consider the capacity and capability of receiving units

Methane:

The Model Medical Command and Control Structure
Bronze: On-Scene commanding, discrete sectors or areas of the incident.

Silver: On-Scene commanders for the entire incident

Gold: Overall offsite command, assisting in provision of resources and plan to return
to normal.

It is important to be familiar with the Operational-Tactical-Strategic terminology also
used by emergency services which differs from the military Tactical-Operational-
Strategic model:

→ Operational: Implement the tactical plan, command the single organization
response, co-ordinates actions.
→ Tactical: Interprets the strategic decision, develops the tactical plan, co-
ordinates activities and assests.
→ Strategic: Sets the strategic direction, co-ordinates responders, priorities
resources.

Scene layout:
Ten Second Triage: (TST)

For non-clinical responders

▪ Set up a Casualty Clearing Station

▪ Each Casualty is assigned a triage category

▪ They are treated as appropriate and brought to the Casualty Clearing Station in
the order of their triage category as resources come available

▪ In the Casualty Clearing Station the patients are re-triaged

▪ Treatment is given as appropriate
 ▪ Patients are transported to the most appropriate facility according to their triage
priority and clinical requirements

Medical advisors:

As a Medical Advisor at a major incident, your role is crucial for coordinating the
medical response, ensuring efficient casualty management, and providing technical
advice to the incident command team. Breakdown of your responsibilities (provided to
you on a card):

1. Wear a Tabard

Why: To clearly identify yourself as the Medical Advisor in charge. This helps
with visibility and ensures all responders can easily recognize your role during
the incident.

2. Check Your Call Sign and Communications (Start a Log)

Ensure you have the correct call sign for the incident.
Confirm all your communication devices are working (e.g., radio, phone).
Start an incident log documenting key decisions, times, and actions. This is
important for accountability and debriefing.

3. Liaise with the Ambulance Incident Commander (Silver)

Get a Briefing: Obtain a situational update from the Ambulance Incident
Commander to understand the scale, type of incident, and key priorities.
Work in conjunction with the Ambulance Incident Commander to coordinate
the triage, treatment, and transportation of casualties.

4. Communication with Receiving Hospitals

Start communication with hospitals to inform them of the nature of the incident
and likely number/type of casualties.
If necessary, liaise with the Strategic Medical Advisor to discuss activating the
P4/T4 (Expectant) triage category for patients who are unlikely to survive
despite treatment.
Regularly brief the Strategic Medical Advisor on the situation, ensuring up-to-
date information flow.
5. Remain at Command Location

Co-locate with either the Ambulance Incident Commander or the Bronze
Commander throughout the incident to facilitate coordination.
Do Not attempt rescue or treatment of casualties yourself—you need to focus
on the bigger picture of coordination.

6. Establish Communication Between Doctors

Establish a communication system between all BASICS/HEMS doctors at the
incident.
Check doctors' IDs to confirm their legitimacy and qualifications. There have
been instances of bogus doctors appearing at major incidents.
Assign doctors to relevant areas: Bronze areas, Casualty Clearing Stations,
and the body holding area.

7. Ensure Effective Flow of Casualties

Work with the Casualty Clearing Officer to ensure that casualties are triaged,
treated, and transported efficiently.
Stay aware of the status of receiving hospital beds, so patients are sent to the
appropriate facilities.
Work with the Ambulance Incident Commander and Strategic Medical
Advisor to explore all available options for evacuating casualties (e.g., air
transport, coaches).

8. Coordinate with Specialist Hospitals

If specialist care is required (e.g., for burns, pediatrics), liaise with the Ambulance
Incident Commander to identify appropriate specialist hospitals and
coordinate transportation.

9. Relief of Medical Staff

Organize relief for medical staff as needed, ensuring there is no fatigue and
that staff are rotated when appropriate.

10. Provide Technical Advice

Act as a technical advisor on medical matters for all services on-site, including
fire, police, and ambulance.
JESIP: Joint Emergency Service Interoperability Principles

▪ Initially JESIP was a two-year programmed that ran from 2012-2014
▪ It was primarily about improving the way the Police, Fire & Rescue and
Ambulance services work together
▪ What JESIP produced was much needed practical guidance to help improve
multi-agency response
▪ The interoperability framework sets out a standard approach to multi-agency
working

The Joint Decision Model: Useful during early stages of an incident, once the situation
develops past this follow a more detailed briefing tool.

IIMARCH – More detailed model

The IMARCH model for a medical advisor at a mass casualty incident:
I – Information

Gather key details: What happened, where, when, how many casualties, and what
might happen next. Know the hazards, and keep updated on the situation.

I – Intent

Clarify goals: efficient triage, treatment, and safe transport of casualties. Ensure
responder safety and aim to prevent further harm.

M – Method

Implement the plan: Set up triage and casualty clearing stations, coordinate transport,
and ensure supplies (antidotes, equipment) are available. Use METHANE for early
reporting.

A – Administration

Organize resources: Allocate roles, manage logistics (supplies, transport), and plan for
staff rotation to avoid fatigue.

R – Risk Assessment

Identify risks: Protect responders from hazards (chemical, structural), ensure safe
evacuation routes, and establish decontamination protocols if needed.

C – Communications

Set up clear communication: Maintain reliable contact between all teams, hospitals, and
command. Provide regular updates on casualty numbers and conditions.

H – Humanitarian Issues

Respect human dignity: Treat casualties with care, offer psychological support, handle
deceased respectfully, and ensure fair, non-discriminatory decisions.
MACA: Military Aid to Civilian Authorities (MACA) is occasionally implemented in the
UK for MMIs.

Military and civilian integration:

Civilian services will have primacy in running the major incident, but the military must
attempt to seamlessly integrate.

n a major incident response, civilian services take the lead, but the military must
integrate smoothly by following these principles:

Co-Locate

Position together with other responders in a single, safe, and easily identifiable location
to ensure collaboration and avoid confusion.

Communicate

Use clear, plain language and avoid jargon or abbreviations. Share information through
METHANE reports when appropriate to maintain clarity.

Co-ordinate

Agree on the lead organization. Identify priorities, capabilities, and limitations to ensure
a coordinated response, including scheduling future meetings.
Jointly Understand Risk

Share information among all parties to understand and manage risks. Agree on control
measures to mitigate hazards.

Share Situational Awareness

Use METHANE reports and the Joint Decision Model to maintain a common
understanding of the situation and ensure coordinated actions.

Multiple casualty incidents:

Consider:

▪ Treatment

▪ Transfer

▪ Destination

▪ Discharge on scene

The correct order for responding to a major incident is:

1. Safety: Ensure the scene is safe before taking any action.
2. Communicate: Establish clear communication with all teams and responders.
3. Read the Scene: Assess the scene to understand the situation and risks.
4. Everyone Accounted For: Ensure all personnel and victims are identified and
accounted for.
5. Assess the Casualties: Evaluate the condition of casualties and their medical
needs.
6. Method of Extraction: Determine how casualties will be safely extracted.
7. Evacuation Route: Identify and secure a clear evacuation route.
8. Right Facility: Ensure casualties are taken to the appropriate medical facility.

SCREAMER can only be fully applied after confirming the scene is safe.

Initial Actions of a Major Incident:

1. Safety: Prioritize personal, scene, and patient safety.
 2. CSCATTT: First responder focuses on command and control, not triage or
treatment unless in a team of 3+.
3. Alert Authorities: Notify Police, Fire, and Ambulance services using a "Major
Incident Alert/Standby" message for incidents with potential for mass casualties.
4. Establish Control Point: Set a control point at your vehicle, ensuring blue lights
stay on, vehicle is parked visibly, and PPE and tabards are worn.
5. Double Crewed Ambulance: Acts as temporary medical command and liaison
until more resources arrive, following JESIP principles.

Triage Sieve:

Once no longer a major incident consider:

When a major incident is no longer in effect, consider the following:

Additional Resources: What further resources may be needed?
Patient Transport: Decide where patients will be sent and by what means.
Alternative Transport: Can patients be moved using non-ambulance options?
Multiple Patients in a DCA: Can you transport more than one patient in a
double-crewed ambulance?
Special Considerations: Are there non-medical reasons for sending patients to
specific hospitals?
On-Scene Discharge: Who can be safely discharged on the scene?

Once the situation is under control, the major incident should be formally cancelled or
stood down. Ensure governance tasks are completed, including event tracking, patient
destinations, and command coordination.
Mental Capacity and Pre-Hospital Mental Health:

Capacity: The ability to understand and perform actions, including having a legal right and
soundness of mind to comprehend the nature and consequences of one's acts.

Lacking Capacity: A person is unable to make a decision due to an impairment or
disturbance in brain function (e.g., dementia, drugs, psychosis).

Mental Capacity Act (MCA) 2005: Provides the legal framework for making decisions for
individuals lacking capacity. It requires compliance when making decisions for those who
lack capacity at the specific time and for a specific matter. Capacity may fluctuate, be
partial or temporary, and relate to one matter but not others.

An assessment that a person lacks capacity to make a decision must never be based on:

Their age.
Their appearance (e.g. scars, features linked to Down’s syndrome, muscle
spasms caused by cerebral palsy).
Assumptions about their condition (e.g., physical disabilities, learning
difficulties, illnesses related to age, and temporary conditions like drunkenness
or unconsciousness).
Any aspect of their behavior (e.g., being extroverted, withdrawn, talking to
themselves, or avoiding eye contact).
Mental Capacity Act 2005: The Mental Capacity Act 2005 provides a statutory framework
for people who lack capacity to make decisions for themselves or who have capacity and
want to prepare for a time when they may lack capacity in the future.

The Act offers the legal framework for acting and making decisions on behalf of
individuals who lack the mental capacity to make (not necessarily all) decisions for
themselves.

The Act balances an individual’s right to make decisions for themselves with their right to
be protected from harm if they lack the capacity to protect themselves.

The MCA codifies many common law principles, such as the doctrine of necessity and
best interests, into an Act.

The MCA 2005 protects human rights in the absence of capacity. It is also important to
consider the Human Rights Act 1998, which protects patient liberty and self-
governance. There are 16 articles in total, including the Right to Life, Right to Liberty and
Security, and the Right to Private Life.

Five Statutory Principles:
Capacity to Consent Form:

Assessment Process:

1. Initial Evaluation: The first stage is to assess whether the person has
an impairment of, or a disturbance in the functioning of their mind
or brain, including mental illness.
2. Decision-Making Ability: Next, determine if the impairment or
disturbance means that the person is unable to make a specific
decision when it needs to be made.
3. Proof of Capacity: Anyone claiming that an individual lacks
capacity must provide evidence.
4. Reasonable Belief: They must demonstrate that they had a
reasonable belief that the individual lacked the capacity to make a
particular decision at the time it needed to be made.
5. Importance of Documentation: This is why the ‘outline your
conversation’ box is crucial; it allows you to include quotes from
your conversation with the patient, supporting your assessment of
their capacity.

Components of Capacity:

▪ Understand: All efforts made help patients understand the decision
and its consequences.
▪ Retain: Short term is acceptable.
▪ Weigh: Weigh up decision.
▪ Communicate

Remember that all four requirements must be met for a patient to have capacity.
Best Interest Decision-Making:

When Time is Limited:

Act in Best Interest: If you have genuine concerns that a patient is at
risk of serious harm, prioritize acting in their best interest. The law and
society typically support the preservation of life.
Escalate Concerns: Utilize all available resources and continue to
escalate the situation as needed.
Court of Protection: In non-emergency situations where there is a
dispute regarding a person’s capacity, the Court of Protection can be
consulted for a judgment.

Factors for Best Interest Assessment:

1. Past and Present Wishes: Consider the individual's past and present
wishes and feelings, along with any relevant written statements made
when they had capacity.
2. Advance Directives: Take into account any advance directives the
person may have established.
3. Known Beliefs and Values: Incorporate their beliefs and values into the
decision-making process.
4. Religion and Culture: Respect the individual's religious and cultural
background.
5. Additional Considerations: Factor in any other elements that the
individual would likely consider if they were able to make decisions.
When taking this action staff must ensure:
They have undertaken the 2- stage capacity assessment
and determined the person lacks capacity to give
informed consent for the care or treatment intervention
proposed.
They have taken account of any advance medical
directive made by the patient that they are aware of.

A capacity assessment will normally be carried out if a patient disagrees with
a suggested course of action.

Two-Stage Capacity Assessment

The first stage asks:

1. Does the person have an impairment of, or a disturbance in the
functioning of, their mind or brain?
a. If the answer is no: The patient should be presumed to have
capacity.
b. If the answer is yes: Proceed to the second part of the
assessment.

The second part of the assessment asks the following questions. Can they:

Understand information about the decision?
Retain that information?
Weigh that information as part of the decision-making process?
 Communicate that decision?

If You Need Advice:

Clinical Support Desk: Sometimes, the clinical support desk can be
useful to persuade patients, acting as the voice of authority on the
telephone.
Police Assistance: As a last (or sometimes first) re